DE3634325C2 - - Google Patents

Description

The invention relates to a pressure vessel consisting of a pre-tensioned with the help of tensioning elements and if necessary basic container body made up of container elements, a gas-tight liner and one inside the container arranged thermal insulation.

Such pressure vessels come for different purposes Use, e.g. B. as storage tanks, as reactors for chemical reactions, especially coal gasification, or as a pressure vessel for nuclear reactors, in particular High temperature reactors.

From DE-PS 26 43 011 is a pressure vessel known type, in which the gas-tight Inner liner directly via a heat-insulating backfill or not with another gas-tight liner on the inner wall of the load-bearing, prestressed container body made of cast iron. A scaffold is provided in the interior of the container Spacers on the inside of the container Attacks the inner surface of the gas-tight liner and by means of the Inner liner and penetrating the thermal insulation Anchoring elements with the container body is connected, e.g. B. via a screw connection. In the  even distribution of connecting elements to be provided provide thermal bridges between the inside of the container and the Container base body. The connecting elements are with welded gas-tight to the inner liner. Backfill and the one that may be between the backfill and the base Liners are under normal pressure.

Furthermore, a prestressed pressure vessel from the DE-PS 26 36 743 known, in which the base body with Cast elements clamped together with prestressing steel consists.

Finally, one is from US-PS 40 44 522 pre-stressed concrete elements with built-up pressure vessels Inner liner known from metal.

It is the object of the present invention based on to create a pressure vessel from DE-PS 26 43 011, where the thermal insulation arrangement without unnecessary Penetrations of the inner liner for safety can be built up and possible pressure change accidents can be absorbed without damage to the container.

This object is achieved in that

• a) the thermal insulation is self-supporting and gas-tight is trained,
• b) thermal insulation through the container body and the liner guided and for the operation of the Pressure vessel connections required for Inside the container is fixed in the container,
• c) the liner from the back with the Container body is connected and
• d) between the thermal insulation and the gas-tight liner a vacuum is maintained.

Due to the self-supporting and gas-tight design of the  Thermal insulation is a connection between thermal insulation and Liner or container body in an even distribution no longer on the outer surface of the insulation required so that thermal bridges are not available. Fixing the self-supporting thermal insulation over the necessary for the operation of the pressure vessel Connections to the inside of the container are sufficient. If necessary, still due to weight reasons Stabilizers in the floor area of the self-supporting Insulation added. By connecting the liner from its back with the container body is the Number of penetrations of the inner liner on the required measure limited.  

When the pressure inside the tank drops quickly as a breakdown due to the vacuum can occur between the outer surface of the gas-tight insulation and the liner no impermissibly high pressure builds up to one Denting or imploding the thermal insulation could result. Even if the pressure is reduced to values below 1 bar is done because of the external vacuum Deformation of the self-supporting thermal insulation is not possible. The gas tightness, especially the Resistance to pressurized hydrogen, further ensures that on the inner surface of the gas-tight liner even at high Operating pressures no drop below dew point for corrosive gases can occur. The vacuum improved at the same time thermal insulation and at the same time allows one Leakage monitoring of thermal insulation and liners.

From DE-PS 9 01 371 is in a device for Cooking pulp in a cooker using a Corrosion protection lining is provided, the application a vacuum between corrosion protection lining and Container or Kocherwandung known to the Connections are held, but there are none Notes can be seen, the liner directly on the inner wall of the container and to the inside of the container arrange a space with a vacuum before the self-supporting gas-tight insulation follows.

Like the basic container body itself made of container elements can be built, it is also possible that self-supporting thermal insulation from individual elements build up. The individual elements can even be gas-tight and evacuated filled with a thermal insulation material Be individual elements, the shell of bad is made of heat-conducting foils or sheets. Such thermal insulation elements are known per se (cf. DE-OS 26 15 299), being used as a thermal insulation material in the Individual elements of diatomaceous earth can be used. The  known heat insulation elements hold high pressures, up to a few hundred bar and high temperatures stood up to over 1000 ° C for a long time and are suitable especially for use in coal gasification, Coal liquefaction or fluidized bed firing of Coal-fired power plants (EP-PS 17 095). When assembling the Elements are welded and, if necessary, filled up the weld joints.

To fasten the liner to the container body are on welded on the outside of the liner bolt and with the Container body connected. This can be the case with cast elements made of metal by screwing while at Container elements or container base bodies made of concrete Anchoring can be done by casting.

It is for maintaining and monitoring the vacuum expedient that preferably with the space between Outer surface of the gas-tight thermal insulation and inner surface of the gas-tight liner at least one vacuum measuring device and at least one vacuum pump controlled by this connected is.

The invention will now be described with reference to the accompanying figure are explained.  

The prestressed pressure vessel ( 1 ) includes a vessel base body ( 2 ) made of several cast elements, which is axially prestressed by prestressing steels ( 3 ) shown schematically and radially by prestressing steels ( 4 ). A gas-tight liner ( 5 ) lies against the inner wall of the container body ( 2 ). Fastening bolts ( 6 ) with a threaded end are welded to the outside of the liner ( 5 ). Nuts ( 7 ) sit on the threaded end and hold the liner ( 5 ) in contact with the container body.

A gas-tight, self-supporting thermal insulation ( 8 ) extends inside the container and is made up of individual plate-shaped containers ( 9 ). The plate-shaped container ( 9 ) is constructed from sheets ( 10 ), and in the evacuable containers is an insulation material ( 11 ), such as. B. powdered diatomaceous earth. The individual containers ( 9 ) are connected to one another by welding ( 12 ).

The space between the thermal insulation ( 8 ) and the gas-tight liner ( 5 ) is connected via a line ( 13 ) to a vacuum pump ( 14 ), which in turn is controlled by a vacuum measuring device ( 15 ) in order to keep a predetermined vacuum value constant.

The vacuum in the space ( Z ) between the thermal insulation ( 8 ) and the liner ( 5 ), which can be of low quality, means that rapid pressure drops can be easily mastered, since there is always overpressure on the thermal insulation ( 8 ). The evacuation load case can also be safely controlled by the vacuum, which can also be used as a control mechanism for the tightness of the thermal insulation ( 8 ) or the liner ( 5 ). Furthermore, there is no formation of condensate in the intermediate space ( Z ) due to the temperature falling below the dew point.

The self-supporting thermal insulation ( 8 ) is essentially held by supply and discharge lines leading to the interior of the container, manipulation devices or the like, of which a supply line ( 16 ) is shown schematically in the figure as an example. Of course, the supply line is led out of the container ( 1 ) so that it cannot itself build a thermal bridge to the liner ( 5 ). It is expedient to lead the liner ( 5 ) or a self-supporting pipe connected to it to the outside and also to lead the insulation inside the pipe to the outside.

It is also possible that the insulation is additionally some claws or the like is supported in the container which for load transfer from internal installations in the container required are.

Claims (3)

1.Pressure container consisting of a container base body ( 2 ) which is prestressed with the aid of clamping elements ( 3 , 4 ) and possibly made up of container elements, a thermal insulation ( 8 ) arranged inside the container and a gas-tight one arranged between the container base body ( 2 ) and the thermal insulation ( 8 ) Liner ( 5 ), characterized in that

• a) the thermal insulation ( 8 ) is self-supporting and gas-tight,
• b) the thermal insulation ( 8 ) is fixed to the inside of the container through connections ( 16 ) through the container base body ( 2 ) and the liner ( 5 ) and required for the operation of the pressure container ( 1 ),
• c) the liner ( 5 ) is connected ( 6, 7 ) from its rear to the container base body ( 2 ) and
• d) a vacuum ( 13 , 14 ) is held between the thermal insulation ( 8 ) and the gas-tight liner ( 5 ).

2. Pressure vessel claim 1, characterized in that for fastening the liner ( 5 ) on the container body ( 2 ) on the outside of the liner ( 5 ) bolts ( 6 ) are welded and connected to the container body ( 2 ). 3. Pressure vessel according to one of claims 1 or 2, characterized in that with the space ( Z ) between the outer surface of the gas-tight insulation ( 8 ) and the inner surface of the gas-tight liner ( 5 ) at least one vacuum measuring device ( 15 ) and at least one through this controlled vacuum pump ( 14 ) is connected.